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Transcript
Chapter 26 *APR Lecture Animation PowerPoint Nutrition and Metabolism To run the animations you must be in Slideshow View. Use the buttons on the animation to play, pause, and turn audio/text on or off. Please Note: Once you have used any of the animation functions (such as Play or Pause), you must first click in the white background before you can advance to the next slide. *See separate FlexArt PowerPoint slides for all figures and tables preinserted into PowerPoint without notes. Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Introduction • Nutrition is the starting point and the basis for all human form and function – The source of fuel that provides the energy for all biological work – The source of raw materials for replacement of wornout biomolecules and cells • Metabolism is the chemical change that lies at the foundation of form and function 26-2 Body Weight and Energy Balance • Weight—determined by the body’s energy balance – If energy intake and output are equal, body weight is stable – Gain weight if intake exceeds output – Lose weight if output exceeds intake – Seems to have a stable, homeostatic set point • Varies from person to person • Combination of heredity and environmental influences – 30% to 50% hereditary – Rest environmental factors such as eating and exercise habits 26-3 Appetite • Control of appetite and body weight includes a still-growing list of peptide hormones and regulatory pathways that control short- and longterm appetite – Gut–brain peptides: act as chemical signals from the gastrointestinal tract to the brain • Short-term regulators of appetite – Mechanisms work over periods of minutes to hours – Makes one feel hungry and begin eating – Makes one feel satiated and end a meal 26-4 Appetite • Short-term regulator—effects last minutes to hours – Ghrelin • Secreted from parietal cells in fundus of empty stomach • Produces sensation of hunger • Stimulates the hypothalamus to secrete growth hormone– releasing hormone – Primes the body to take best advantage of the nutrients about to be absorbed • Ghrelin secretion ceases within an hour of eating • Signal that begins a meal 26-5 Appetite Cont. – Peptide YY (PYY) • Secreted by enteroendocrine cells of ileum and colon • Sense that food has arrived in the stomach • Secrete PYY long before chyme reaches the ileum in amounts proportionate to calories consumed • Primary effect is to signal satiety and terminate eating • Signal that ends a meal – Cholecystokinin (CCK) • Secreted by enteroendocrine cells in duodenum and jejunum • Stimulates the secretion of bile and pancreatic enzymes • Stimulates the brain and sensory fibers of the vagus nerve suppressing appetite 26-6 Appetite • Long-term regulators—governs one’s average rate of caloric intake and energy expenditure over periods of weeks to years • These two peptides inform the brain of how much adipose tissue the body has and activates mechanisms for adding or reducing fat – Leptin • • • • Secreted by adipocytes throughout the body Level proportionate to one’s own fat stores Informs brain on how much body fat we have Obese people are more likely to have a receptor defect than hormone deficiency 26-7 Appetite Cont. – Insulin • • • • Secreted by pancreatic beta cells Stimulates glucose and amino acid uptake Promotes glycogen and fat synthesis Has receptors in the brain and functions, like leptin, as an index of the body’s fat stores • Weaker effect on appetite than leptin 26-8 Gut–Brain Peptides in Appetite Regulation Satiety Hunger Forebrain – + NPYsecreting neurons Arcuate nucleus of hypothalamus Melanocortinsecreting neurons + – Key Secretion + Stimulatory effect – Inhibitory effect Insulin Ghrelin Leptin PYY CCK Figure 26.1 PYY Small intestine Pancreas Stomach Adipose tissue Large intestine PYY Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. 26-9 Obesity • Obesity—weight more than 20% above recommended norm for one’s age, sex, and height – U.S. rates • 30% obese • 35% overweight • Body mass index (BMI)—indication of overweight or obese – BMI = W/H2 (W = weight in kg; H = height in meters) • 20 to 25 is optimal for most people • Over 27: overweight • Above 30: obese 26-10 Obesity • Shortens life expectancy – Increased risk of atherosclerosis; hypertension; diabetes mellitus; joint pain; kidney stones and gallstones; cancer of uterus, breast, and prostate; and sleep apnea • Causes are diverse and unknown – Heredity, overfeeding in infancy, and problems with appetite and weight-regulating mechanisms are suspected 26-11 Appetite • Hunger is stimulated partly by gastric peristalsis – Mild hunger contractions begin soon after stomach is empty – Increase in intensity over a period of hours – Do not affect the amount of food consumed 26-12 Appetite • Appetite is briefly satisfied by: – Chewing and swallowing – Stomach filling – Lasting satiation depends upon nutrients entering blood • Neurotransmitters stimulate desire for different types of food – Norepinephrine: carbohydrates – Galanin: fats – Endorphins: protein 26-13 Calories • One calorie—amount of heat required to raise temperature of 1 g of water 1°C – 1,000 calories is a kilocalorie (kcal) or Calorie – A measure of the capacity to do biological work • Carbohydrates and proteins yield about 4 kcal/g – Sugar and alcohol (7.1 kcal/g) are “empty” calories • Few nutrients and suppress appetite 26-14 Calories • Fats yield about 9 kcal/g • Good nutrition requires complex foods that meet the body’s needs for protein, lipid, vitamins, and other nutrients • Fuel—substance solely or primarily oxidized to extract energy from it – Extracted energy used to make adenosine triphosphate (ATP) 26-15 Nutrients • Nutrient—any ingested chemical used for growth, repair, or maintenance of the body • Six classes of nutrients – Water, carbohydrates, lipids, and proteins • Macronutrients—must be consumed in relatively large quantities – Vitamins and minerals • Micronutrients—only small quantities are required 26-16 Nutrients • Recommended daily allowances (RDA) – Safe estimate of daily intake that would meet the nutritional needs of most healthy people • Essential nutrients cannot be synthesized in body – Minerals, most vitamins, eight amino acids, and one to three of the fatty acids must be consumed in diet 26-17 Carbohydrates • Well-nourished adult body has 440 g of carbohydrates – 325 g of muscle glycogen – 90 to 100 g of liver glycogen – 15 to 20 g of blood glucose • Sugars function as: – Structural components of other molecules including nucleic acids, glycoproteins, glycolipids, ATP, and related nucleotides (GTP, cAMP) 26-18 Carbohydrates • Blood glucose concentration carefully regulated – Interplay of insulin and glucagon – Regulate balance between glycogen and free glucose • Carbohydrate intake influences metabolism of other nutrients – Fats used as fuel when glucose and glycogen levels are low – Excess carbohydrates are converted to fat 26-19 Carbohydrates • Dietary carbohydrates in three principal forms – Monosaccharides: glucose, galactose, fructose • Arise from digestion of starch and disaccharides • Small intestine and liver convert galactose and fructose to glucose – Ultimately, all carbohydrate digestion generates glucose – Outside hepatic portal system, only blood sugar is glucose – Normal blood sugar concentration: 70 to 110 mg/dL – Disaccharides: sucrose (table sugar), maltose, lactose – Polysaccharides (complex carbohydrates): starch, glycogen, and cellulose (not a nutrient because it is not digested, but important as dietary fiber) 26-20 Fiber • Dietary fiber—all fibrous material of plant and animal origin that resists digestion – Cellulose, pectin, gums, and lignins • Fiber is important to diet—RDA is 30 g/day • Water-soluble fiber (pectin) – Found in oats, beans, peas, brown rice, and fruits – Decreases blood cholesterol and LDL levels 26-21 Fiber • Water-insoluble fiber (cellulose, hemicellulose, lignin) – No effect on cholesterol and LDL levels – Absorbs water in intestines, softens stool, increases bulk 40% to 100%, stretches colon, and stimulates peristalsis thereby quickening passage of feces – No clear effect on incidence of colorectal cancer – Excessive intake can interfere with absorption of elements such as iron, calcium, magnesium, phosphorus, and other trace elements 26-22 Lipids • Reference male 15% body fat; reference female 25% body fat • Well-nourished adult meets 80% to 90% of resting energy needs from fat – Fat is superior to carbohydrates for energy storage for two reasons • Carbohydrates are hydrophilic, absorb water, and expand and occupy more space in the tissues, and fat is hydrophobic, contains almost no water, and is a more compact energy storage substance • Fat is less oxidized than carbohydrates and contains over twice as much energy: 9 kcal/g for fat; 4 kcal/g for carbohydrates 26-23 Lipids • Fat has glucose-sparing and protein-sparing effects when used for energy needs – Glucose is spared for consumption by cells that cannot use fat, like neurons – Protein not catabolized for fuel • Fat-soluble vitamins (A, D, E, K) absorbed with dietary fat – Ingestion of less than 20 g/day risks vitamin deficiency 26-24 Lipids • Diverse functions besides energy source – Structural • Phospholipids and cholesterol are components of plasma membranes and myelin – Chemical precursors • Cholesterol—a precursor of steroids, bile salts, vitamin D • Thromboplastin, an essential blood-clotting factor, is a lipoprotein • Fatty acids—arachidonic acid and linoleic acid: precursors of prostaglandins and other eicosanoids – Important protective and insulating functions 26-25 Lipids • Requirements: should be less than 30% of daily calorie intake – Typical American gets 40% to 50% from fat • Most fatty acids synthesized by body – Essential fatty acids must be consumed 26-26 Lipids • Sources – Saturated fats • Animal origin—meat, egg yolks, dairy products – Unsaturated fats • Found in nuts, seeds, and most vegetable oils – Cholesterol • Found in egg yolks, cream, shellfish, organ meats, and other meats • Does not occur in foods of plant origin 26-27 Cholesterol and Serum Lipoproteins • Serum lipoproteins are classified into four major categories by their density – – – – Chylomicrons: 75–1,200 nm in diameter Very low–density lipoproteins (VLDLs): 30–80 nm Low-density lipoproteins (LDL): 18–25 nm High-density lipoproteins (HDL): 5–12 nm • Their most important differences are in composition and function 26-28 Lipoprotein Processing Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Chylomicron Very low–density lipoprotein Low-density lipoprotein (LDL) High-density lipoprotein (HDL) Key Phospholipid Phospholipid (3%) Phospholipid (17%) Phospholipid (21%) Phospholipid (25%) Triglyceride Triglyceride (90%) Triglyceride (55%) Triglyceride (6%) Triglyceride (5%) Cholesterol Cholesterol (5%) Cholesterol (20%) Cholesterol (53%) Cholesterol (20%) Protein Protein (2%) Protein (8%) Protein (20%) Protein (50%) (a) Lipoprotein types Figure 26.2a 26-29 Cholesterol and Serum Lipoproteins • Chylomicrons form in absorptive cells of small intestine • Enter lymphatic system, then bloodstream • Blood capillary endothelial cells have lipoprotein lipase to hydrolyze triglycerides into monoglycerides and free fatty acids 26-30 Cholesterol and Serum Lipoproteins • Most of the body’s cholesterol is endogenous— internally synthesized rather than dietary – – – – Body compensates for variation in intake High dietary intake lowers liver cholesterol production Low dietary intake raises liver production Lowering dietary cholesterol lowers level by no more than 5% – Certain saturated fatty acids (SFAs) raise serum cholesterol level • Moderate reduction in SFAs can lower blood cholesterol by 15% to 20% 26-31 Cholesterol and Serum Lipoproteins • Vigorous exercise lowers blood cholesterol – Sensitivity of right atrium to blood pressure is reduced – Heart secretes less atrial natriuretic peptide and thus kidneys excrete less sodium and water – Raises blood volume – Dilution of blood lipoproteins causes adipocytes to produce more lipoprotein lipase – Adipocytes consume more blood triglycerides – VLDL particles shed some cholesterol which is picked up by HDL and removed by the liver 26-32 Cholesterol and Serum Lipoproteins • Levels of LDL – High LDL is a warning sign – Correlates with cholesterol deposition in arteries – Elevated by saturated fat intake, cigarette smoking, coffee, and stress • Levels of HDL – High level of HDL is beneficial – Indicates that cholesterol is being removed from the arteries and transported to the liver for disposal 26-33 Cholesterol and Serum Lipoproteins • Recommendations – Increase your ratio of HDL to LDL – Regular aerobic exercise – Avoid smoking, saturated fats, coffee, stress 26-34 Lipoprotein Processing Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Chylomicron pathway Lymph absorbs chylomicrons from small intestine Cells absorb LDLs by receptor-mediated endocytosis VLDL/LDL pathway Lymph drains into bloodstream Triglycerides removed and stored in adipocytes Lipoprotein lipase removes lipids from chylomicrons Liver disposes of chylomicron remnants Lipids are stored in adipocytes or used by other cells VLDLs become LDLs containing mainly cholesterol Liver produces VLDLs Liver produces empty HDL shells HDL shells pick up cholesterol and phospholipids from tissues Filled HDLs Liver excretes return to liver excess cholesterol and bile acids HDL pathway (b) Lipoprotein-processing pathways Figure 26.2b 26-35 Proteins • Protein constitutes 12% to 15% of total body mass – 65% of it is in skeletal muscle • Functions – Muscle contraction – Motility of cilia and flagella – Structural components • All cellular membranes – Receptors, pumps, ion channels, and cell-identity markers • Fibrous proteins – Collagen, elastin, and keratin make up much of the structure of bone, cartilage, tendons, ligaments, skin, hair, and nails 26-36 Proteins Cont. • Globular proteins – Antibodies, hormones, myoglobin, neuromodulators, hemoglobin, and about 2,000 enzymes that control nearly every aspect of cellular metabolism • Plasma proteins – Albumins and other plasma proteins that maintain blood viscosity and osmolarity and transport lipids and some other plasma solutes – Buffer pH of body fluids – Contributes to resting membrane potential of all cells 26-37 Proteins • Protein RDA is 44 to 60 g/day – Weight in pounds x 0.37 = estimate of RDA of protein – Higher intake recommended under conditions of stress, infection, injury, and pregnancy – Excessive intake overloads the kidneys with nitrogenous waste and can cause kidney damage 26-38 Proteins • Nutritional value of a protein depends on right proportions of amino acids needed for human proteins – 8 essential amino acids cannot be synthesized by the body • Isoleucine, leucine, lysine, methionine, phenylalanine, threonine, tryptophan, and valine – 12 inessential amino acids synthesized by the body if the diet does not supply them • Cells do not store surplus amino acids for later use – When a protein is synthesized, all amino acids must be present at once – If one is missing, the protein cannot be synthesized 26-39 Proteins • Complete proteins—high-quality dietary proteins that provide all of the essential amino acids in the necessary proportions for human tissue growth, maintenance, and nitrogen balance • Incomplete proteins—lower quality because they lack one or more essential amino acids 26-40 Minerals and Vitamins • Minerals—inorganic elements that plants extract from the soil or water and introduce into the food web • Vitamins—small dietary organic compounds that are necessary to metabolism • Neither is used as fuel • Both are essential to our ability to use other nutrients 26-41 Minerals and Vitamins • Minerals constitute about 4% of the body mass – Three-quarters being calcium and phosphorus in bones and teeth – Phosphorus • Key structural component of phospholipids, ATP, cAMP, GTP, and creatine phosphate • Basis for the phosphate buffer system – Calcium, iron, magnesium, and manganese function as cofactors for enzymes 26-42 Minerals and Vitamins Cont. – Iron is essential for the oxygen-carrying capacity of hemoglobin and myoglobin – Chlorine: component of stomach acid – Many mineral salts function as electrolytes and govern function of nerve and muscle cells, osmotically regulate the content and distribution of water in the body, and maintain blood volume • Plants are the best source of minerals 26-43 Minerals • Vegetables, legumes, milk, eggs, fish, and shellfish • Animal tissues contain large amounts of salt – Carnivores rarely lack salt in their diets – Herbivores often supplement by ingesting salt from soil • Recommended sodium intake is 1.1 g/day • Typical American diet contains 4.5 g/day • Hypertension can be caused by elevated salt intake 26-44 Vitamins • Water-soluble vitamins (C, B complex) – Absorbed with water in small intestine – Quickly excreted by the kidneys, not stored, and seldom accumulate to excess 26-45 Vitamins Cont. – Vitamin C (ascorbic acid) • Promotes hemoglobin synthesis, collagen synthesis, and sound connective tissue structure • An antioxidant that scavenges free radicals and possibly reduces the risk of cancer – B vitamins • Function as coenzymes or parts of coenzyme molecules • Assist enzymes by transferring electrons from one metabolic reaction to another • Making it possible for enzymes to catalyze these reactions 26-46 Vitamins • Fat-soluble vitamins – Incorporated into lipid micelles in the small intestine and absorbed with dietary lipids – Vitamin A • Component of visual pigments • Promotes proteoglycan synthesis and epithelial maintenance – Vitamin D • Promotes calcium absorption and bone mineralization – Vitamin K • Essential for prothrombin synthesis and blood clotting – Vitamins A and E • Antioxidants like ascorbic acid 26-47 Vitamins • Diseases resulting from vitamin deficiencies or excesses • Hypervitaminosis—vitamin excess • Vitamin A deficiency—night blindness, dry skin and hair, dry conjunctiva and cloudy cornea, and increased incidence of urinary, digestive, and respiratory infections – World’s most common vitamin deficiency 26-48 Vitamins • Vitamin A excess—may cause anorexia, nausea and vomiting, headache, pain and fragility in the bones, hair loss, an enlarged liver and spleen, and birth defects • Vitamins B6, C, D, and E have also been implicated in toxic hypervitaminosis • Megavitamins—doses 10 to 1,000 times the RDA show no effect on performance 26-49 Carbohydrate Metabolism • Dietary carbohydrate burned as fuel within hours of absorption • All oxidative carbohydrate consumption is essentially a matter of glucose catabolism C6H12O6 + 6 O2 6 CO2 + 6 H2O • Function of this reaction is to transfer energy from glucose to ATP – Not to produce carbon dioxide and water 26-50 Glucose Catabolism • Glucose catabolism—a series of small steps, each controlled by a separate enzyme, in which energy is released in small manageable amounts, and as much as possible, is transferred to ATP and the rest is released as heat 26-51 Glycolysis and Anaerobic Fermentation Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Key Glucose Carbon atoms ATP Phosphate groups 1 Phosphorylation ADP Glucose 6-phosphate Glycogen Fat Fructose 6-phosphate ATP 2 Priming ADP Fructose 1,6-diphosphate 3 Cleavage 2 PGAL 2 Pi 2 NAD+ 2 NADH + 2 H+ 4 Oxidation 2 2 ADP 2 H2O 2 ATP 2 5 Dephosphorylation 2 ADP 2 ATP 2 2 pyruvic acid Figure 26.3 2 NADH + 2 H+ 2 NAD+ 2 2 lactic acid 26-52 Anaerobic fermentation Aerobic respiration Anaerobic Fermentation • Anaerobic fermentation—in absence of oxygen, the cell resorts to this one-step reaction – NADH donates a pair of electrons to pyruvic acid reducing it to lactic acid – Regenerating NAD+ • Lactic acid leaves the cells that generate it – Enter bloodstream and transported to the liver – When oxygen becomes available the liver oxidized it back to pyruvic acid – Oxygen is part of the oxygen debt created by exercising muscle 26-53 The Mitochondrial Matrix Reactions Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Pyruvic acid (C3) 6 CO2 NAD+ 7 NADH + H+ Acetyl group (C2) 8 Acetyl-CoA Coenzyme A H2O 9 Citric acid (C6) Oxaloacetic acid (C4) H2O 10 NADH + H+ NAD+ (C6) Citric acid cycle 18 H2O NAD+ 11 NADH + H+ (C4) 12 CO2 17 (C5) H2O 13 Occurs in mitochondrial matrix (C4) NADH + H+ 14 16 FADH2 NAD+ (C4) Figure 26.4 CO2 FAD (C4) Pi 15 GTP GDP 26-54 ADP ATP Electron Transport • Oxygen is the final electron acceptor – Each oxygen atom accepts two electrons from cytochrome a3 and two protons from the mitochondrial matrix forming water • Body’s primary source of metabolic water—water synthesized in the body – This reaction explains the body’s oxygen requirement – No oxygen, cell produces too little ATP to sustain life 26-55 Chemiosmotic Mechanisms of ATP Synthesis Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Intermembrane space Matrix Cristae Figure 26.6 Inner membrane Outer membrane NADH + H+ ½ O2 + 2 H+ NAD+ H2O 6 H+ Matrix 2e– Inner membrane Enzyme complex 1 CoQ 2e– 2e– Enzyme complex 2 Enzyme complex 3 3 ADP + 3 Pi 3 ATP ATP synthase Cyt c Intermembrane space 2 H+ 2 H+ 2 H+ Outer membrane 26-56 ATP Generated by Oxidation of Glucose Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Glucose 2 ATP Glycolysis (net) 2 NADH + 2 H+ Cytosol 2 pyruvate Mitochondria 2 NADH + 2 H+ CO2 6 NADH + 6 H+ Citric acid cycle 2 ATP 2 FADH2 Electron-transport chain O2 H2O Figure 26.7 4 ATP 28–30 ATP Total 36–38 ATP 26-57 Glycogen Metabolism • ATP is quickly used after it is formed – It is an energy transfer molecule, not an energy storage molecule – Converts the extra glucose to other compounds better suited for energy storage (glycogen and fat) • Glycogenesis—synthesis of glycogen – Stimulated by insulin – Chains glucose monomers together 26-58 Glycogen Metabolism • Glycogenolysis—hydrolysis of glycogen – Releases glucose between meals – Stimulated by glucagon and epinephrine – Only liver cells can release glucose back into blood • Gluconeogenesis—synthesis of glucose from noncarbohydrates, such as glycerol and amino acids – Occurs chiefly in the liver and later, kidneys if necessary 26-59 Major Pathways of Glucose Storage and Use Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Blood glucose Extracellular Intracellular Glucose 6-phosphatase (in liver, kidney, and intestinal cells) Hexokinase (in all cells) Glucose 6-phosphate Glycogen synthase Key Pi Glucose 1-phosphate Glycogenesis Glycogenolysis Glycogen phosphorylase Glycogen Pi Glycolysis Figure 26.8 26-60 Lipids • Triglycerides are stored in body’s adipocytes – Turnover of lipid molecules every 2 to 3 weeks • Released into blood, transported and either oxidized or redeposited in other fat cells • Lipogenesis—synthesis of fat from other types of molecules – Amino acids and sugars used to make fatty acids and glycerol – PGAL can be converted to glycerol 26-61 Lipids • Lipolysis—breaking down fat for fuel – Begins with the hydrolysis of a triglyceride to glycerol and fatty acids – Stimulated by epinephrine, norepinephrine, glucocorticoids, thyroid hormone, and growth hormone – Glycerol easily converted to PGAL and enters the pathway of glycolysis • Generates only half as much ATP as glucose 26-62 Lipids Cont. – Beta oxidation in the mitochondrial matrix catabolizes the fatty acid components • Removes 2 carbon atoms at a time which bonds to coenzyme A • Forms acetyl-CoA, the entry point for the citric acid cycle – A fatty acid with 16 carbons can yield 129 molecules of ATP • Richer source of energy than the glucose molecule 26-63 Lipogenesis and Lipolysis Pathways Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. Glucose Glucose 6-phosphate Stored triglycerides Glycerol PGAL Fatty acids Glycerol Beta oxidation Pyruvic acid Fatty acids Acetyl groups New triglycerides Acetyl-CoA Ketone bodies β-hydroxybutyric acid Acetoacetic acid Acetone Citric acid cycle Figure 26.9 Key Lipogenesis Lipolysis 26-64 Lipids • Fatty acids catabolized into acetyl groups (by beta oxidation in mitochondrial matrix) may: – Enter citric acid cycle as acetyl-CoA – Undergo ketogenesis • Metabolized by liver to produce ketone bodies – Acetoacetic acid – -hydroxybutyric acid – Acetone • Rapid or incomplete oxidization of fats raises blood ketone levels (ketosis) and may lead to a pH imbalance (ketoacidosis) 26-65 Proteins • Amino acid pool—dietary amino acids plus 100 g of tissue protein broken down each day into free amino acids • May be used to synthesize new proteins – Fastest rate of cell division is epithelial cells of intestinal mucosa • Of all the amino acids absorbed by the small intestine: – 50% come from the diet – 25% from dead epithelial cells – 25% from enzymes that have digested each other 26-66 Hepatitis and Cirrhosis • Hepatitis or inflammation of the liver is caused by one of five strains of hepatitis viruses – Hepatitis A is common and mild • Causes up to 6 months of illness, but most recover – Hepatitis B and C are more serious • Transmitted sexually and through blood and other body fluids • Often lead to cirrhosis or liver cancer • Cirrhosis—irreversible inflammatory liver disease – Scar tissue starts to dominate, vessels rupture, and necrosis occurs – Results from alcohol abuse 26-67 Metabolic States and Metabolic Rate • Your metabolism changes from hour to hour – Depending on how long since your last meal • Absorptive (fed) state – About 4 hours during and after a meal – Nutrients are being absorbed – Nutrients may be used immediately to meet energy and other needs • Postabsorptive (fasting) state – Prevails in the late morning, late afternoon, and overnight – Stomach and intestines are empty – Body’s energy needs are met from stored fuels 26-68 Metabolic Rate • Metabolic rate—the amount of energy liberated in the body in a given period of time (kcal/hr or kcal/day) – Calorimeter: a closed chamber with water-filled walls that absorb the heat given off by the body – Measured indirectly with a spirometer by measuring the amount of oxygen a person consumes • Metabolic rate depends on physical activity, mental state, absorptive or postabsorptive status, thyroid hormone, and other hormones 26-69 Metabolic Rate • Basal metabolic rate (BMR) – A baseline or standard of comparison that minimizes the effects of the variables – Relaxed, awake, fasting, comfortable room temperature – Adult male BMR is 2,000 kcal/day (slightly less for a female) 26-70 Metabolic Rate • Total metabolic rate (TMR)—the sum of the BMR and energy expenditures for voluntary activities, especially muscle contraction • Factors raising TMR – Pregnancy, anxiety, fever, eating, catecholamines and thyroid hormones – High in children and decreases with age • Factors lowering TMR – Apathy, depression, and prolonged starvation – As one reduces food intake, the body reduces its metabolic rate to conserve body mass, making weight loss more difficult 26-71 Disturbances of Thermoregulation • Fever – Normal protective mechanism that should be allowed to run its course if it is not excessively high – Above 108° to 110°F can be very dangerous • Elevates the metabolic rate • Body generates heat faster than heat-losing mechanisms can disperse it • Causes dangerous positive feedback loop • Core temperatures of 111° to 113°F promote metabolic dysfunction, neurological damage, and death 26-72 Disturbances of Thermoregulation • Exposure to excessive heat – Heat cramps: painful muscle spasms due to electrolyte imbalance from excessive sweating • Occur especially when a person begins to relax after strenuous exertion and heavy sweating – Heat exhaustion: from severe water and electrolyte loss • Hypotension, dizziness, vomiting, and sometimes fainting 26-73 Disturbances of Thermoregulation Cont. – Heat stroke (sunstroke): state in which the core body temperature is over 104°F • Brought about by prolonged heat wave with high humidity • Skin is hot and dry • Nervous system dysfunctions—delirium, convulsions, or coma • Tachycardia, hyperventilation, inflammation and multiorgan dysfunction, death 26-74 Disturbances of Thermoregulation • Exposure to excessive cold – Hypothermia can cause life-threatening positive feedback loops – If core temperature drops below 91°F • Metabolic rate drops so low that heat production cannot keep pace with heat loss • Temperature falls even more • Death from cardiac fibrillation may occur below 90°F • Some people survive body temperatures as low as 84°F in a state of suspended animation • Below 74°F is usually fatal • Dangerous to give alcohol to someone in hypothermia, as it accelerates heat loss by dilating cutaneous vessels 26-75 Alcohol and Alcoholism • Alcohol—mind-altering drug, empty calories, addictive drug, and a toxin • Rapidly absorbed from GI tract – – – – 20% in stomach and 80% in small intestine Carbonation increases rate of absorption Food reduces absorption Easily crosses blood–brain barrier to exert intoxicating effects on the brain 26-76 Alcohol and Alcoholism • Detoxified by hepatic enzyme alcohol dehydrogenase which oxidizes it to acetaldehyde—in citric cycle is oxidized to CO2 and H2O – Women have less alcohol dehydrogenase and clear alcohol from the bloodstream more slowly than men • More vulnerable to alcohol-related illnesses such as cirrhosis of the liver 26-77 Physiological Effects of Alcohol • Nervous system – Depressant because it inhibits the release of norepinephrine and disrupts GABA receptors • Low dose provides euphoria and giddiness • High dose—nerves less responsive to neurotransmitters – Timing and coordination between neurons is impaired – Slurred speech, poor coordination, slower reaction time 26-78 Physiological Effects of Alcohol • Liver – Excessive acetaldehyde produced during metabolism causes inflammation of liver and pancreas • Disruption of digestive function – Destroys hepatocytes faster than they can regenerate, producing cirrhosis • Hepatic coma and jaundice 26-79 Physiological Effects of Alcohol • Circulatory system – Clotting problems • Clotting factors reduced due to liver damage – Edema due to inadequate production of albumin – Cirrhosis obstructs hepatic portal circulation – Portal hypertension and hypoproteinemia • Liver and other organs “weep” serous fluid into peritoneal cavity • Ascites—swelling of abdomen with as much as several liters of serous fluid • Hemorrhaging and hematemesis (vomiting blood) • Destroys myocardial tissue, reduces heart contractility, and causes arrhythmias 26-80 Physiological Effects of Alcohol • Digestive system and nutrition – Breaks down protective mucous barrier of stomach • Gastritis and bleeding • Linked to esophageal cancer and peptic ulcers – Malnutrition from appetite suppression – Acetaldehyde interferes with vitamin absorption and use 26-81 Addiction • Alcohol is the most widely available addictive drug in America – Similar to barbiturates in toxic effects • Potential for tolerance, dependence, and risk of overdose – Physiological tolerance of high concentrations – Impaired physiological, psychological, and social functionality – Withdrawal symptoms when intake is reduced or stopped: delirium tremens (DT) • Restlessness, insomnia, confusion, irritability, tremors, incoherent speech, hallucinations, convulsions, and coma • Has 5% to 15% mortality rate 26-82